The present invention relates generally to tie-supported railroad tracks and, more particularly, to systems and methods for automatically pre-fabricating plated railroad ties and sections of railroad track, remote from an installation site.
In regard to plating wooden railroad ties, traditionally such has been labor-intensive, including manual placement of the plates at gauge-defining spaces on top of each tie, but also manual effort to insert the spikes, with a suitable tool, into the ties through apertures in the plates. Sometimes the ties are pre-drilled using human labor to control the drilling. The formation of prefabricated sections of railroad track has not been typically done off-site. Typically, it has been done on-site, where railroad line construction or repair is taking or is to take place.
In brief summary, the present invention overcomes or substantially alleviates time-consuming and labor-intensive problems of the past related to accurately securing tie plates to railroad ties and constructing sections of complete railroad tracks. More specifically, the present invention is directed to novel systems and methods for automated creation of plated ties and/or pre-fabricated sections of railroad track away from and for shipment to an installation site.
As is apparent in the industry and from U.S. Pat. Nos. 6,546,612 and 6,681,474, pre-plating railroad ties typically has not been automated, but has been time-intensive and labor-intensive, even when tools, under human control, are used. Automatic pre-fabrication of entire sections of railroad track away from and for unitary shipment to an installation site, has not been within typical prior art practices.
With the foregoing in mind, it is a primary object of the present invention to overcome or substantially alleviate problems of the past related to time-intensive and labor-intensive pre-plating of railroad ties and pre-fabrication of sections of railroad track.
Another paramount objective is the provision of essentially automated novel systems and distinct methodologies for plating wooden railroad ties in a time efficient way, with little or inconsequential manual labor.
Another critical object is the automated production of sections of railroad track remote from and for shipment to an installation site.
A further significant object of the invention is the provision of systems and methods for automatically creating plated ties from drilled wooden ties, plates and spikes and the automatic creation of pre-fabricated sections of railroad track using the plated ties and also railroad rails, at one or more sites remote from and for shipment to one or more installation sites.
An additional object of value is the provision of clips by which the adjacent ties forming a part of a section of pre-fabricated railroad track are restrained from migrating to or fro in respect to the rails, both during transporting of the track section to the installation site, during installation and after installation as part of an operative railroad line.
Another paramount objective is to utilize robotics to aid in automatically assembling pre-plated wood railroad ties and to aid in automatically pre-fabricating sections of railroad track.
These and other objects and features of the present invention will be apparent from the following detailed description, taken with reference to the accompanying drawings.
In respect to terminology, the outside lower flange of each rail is called a field flange, while the inside lower flange of each rail is called a gauge flange. Likewise, the part of each plate outside each rail of a railroad track is called the field part and the apertures therein are called field apertures. The part of each plate inside each rail of a railroad track is called the gauge part and the apertures therein are called gauge apertures. Spikes driven through the field apertures of any plate are called field spikes. Spikes driven through the gauge aperture of any plate are called gauge spikes. The central part of each plate, which receives a rail is sloped downward slightly at its upper surface toward the gauge side of the plate.
This specification contains numerous references to cylinder assemblies comprising an external cylinder, an internal piston and an exposed reciprocal piston rod connected at one end to the piston and exposed at the other end beyond the cylinder. This cylinder assembly technology is well known and, therefore, need not be described herein in detail. Unless otherwise stated, all cylinder assemblies mentioned herein are two way assemblies pneumatically operated using two ports on the cylinder.
This specification refers to spaced stations or sites, where ties are drilled, plates are made contiguous with the ties and spikes are inserted through apertures in the plates into drill holes in the ties. For ease of presentation, certain mechanisms are shown in the singular, but it should be understood that a plurality of such mechanisms can and preferably sometimes are used either simultaneously or consecutively to increase the rate at which plated ties and pre-fabricated sections of railroad track are assembled.
Reference is now specifically made to the drawings, wherein like numerals are used to designate like parts throughout. In respect to the disclosed embodiments, it is presently preferred that computer-controlled robots comprise mechanisms which command some of the automated processes and equipment by which ties are pre-plated and sections of railroad track are prefabricated.
In respect to
Referring still to the embodiment of
In reference again to
Each stack or bundle 103 of ties 102 comprise horizontal rows and vertical columns of ties arranged as shown in
With a stack 103 of ties 102 placed at the entry station, as shown in
As a row 103 of ties 102 approaches the tie separation station 114, the ties 102 are caused to become automatically essentially uniformly spaced, by forces 116, one from the next so that a spaced and a parallel relationship between the ties 102 (
With the ties 102 arranged as shown in
Reference is now made to
The two plates 134 are positioned as illustrated in
The plated ties 102/134 are, thereafter, displaced, as shown by displacement path 170 in
Reference is now made to
Two rails 200, each comprising two oppositely-directed lower flanges 202, are automatically delivered from a source of railroad rails 192 along paths 194 and 196, so as to be aligned with the two linearly aligned sets of plates 134 secured to ties 102 at support 190. The two railroad rails 200 are automatically displaced, as depicted by paths 196, so as so slide under the somewhat elevated heads 161 of the rail-retaining spikes 158 and along the central channels 157 of the aligned sets of plates 134 until the rails 200 rest appropriately on the upper surface of central portions 157 of the associated series of plates 134. It should be understood that one end of each rail may typically extend a given distance beyond the distal tie of the track section, with the other proximal end being located at the midpoint of the proximal tie of the track section, to accommodate installation on a railroad line of successive rail track sections.
When the rails 200 are in the fully inserted accurate position, the partially inserted rail-retaining spikes 158, directly adjacent to the rails 102, with the eccentric heads 161 above and overlapping the lower flanges 202 of the rails 200 are fully force-inserted into the ties 102. These spikes 158 are automatically forced downward so that the eccentric heads 161 of these spikes 158 become firmly and retainingly contiguous with the adjacent lower flanges 202 of the rails 200, thereby unifying the rails, the plates and the ties.
To assure that there is no relative movement between the rails 200 and the ties 102 after they are assembled together, and the rail-retaining spikes 158 are inserted and retained stationarily contiguous with the lower flanges 202 of the rails 200, space-retaining clips or anchors 230 are forced-fit onto the lower flanges 202 of both rails 200, so as to hold firm the entire space between all adjacent ties forming part of the track section.
A cylinder/piston-carrying jig, generally designated 220, is automatically lowered into the position of
The piston rods 225 extending from cylinders 226 (
The abutments or rams 228 are respectively connected to the distal ends of the exposed oppositely-directed piston rods 225 of the associated cylinders 226. Each group of clips 230 is automatically loaded against the abutments or rams 228, so that each clip 230 is initially directly above each of the associated rail 200.
Thereafter, the cradles 232, each carrying a group of clips 230, are lowered, along with the cylinders 234 and piston rods 244, by downward extension of vertical piston rod 240 of the central vertical cylinder 242 from the position of
As the piston rods 244 are extended, the cradles 232 and the clips 230 are displaced toward and under the spaced rails 200. When the clips 230 pass under the rails, the interior and exterior lobes thereof, both of which face upward, are force-fit or snapped over the lower field and gauge flanges 202 of both rails 200, to be there securely retained as stationary spacers holding the rails and the ties immovably together, with the ties spaced precisely as required for the track section as part of an operating rail line.
Next, the piston rods 244 are retracted into the cylinders 234 and the empty carriers 232 and cylinder-piston rod assemblies 234/244 are elevated to their positions of
With reference to
Reference is now made to the second embodiment of the present invention, the processing steps which are illustrated in
It is to be understood that utilization of a support frame, generally designated 300, is presently preferred, upon which the structures for processing railroad ties and prefabricated sections of railroad track are supported. It is expected that standard structural members of steel, aluminum or composite materials will be used and such will also use connectors so as to provide a rigid framework of a well-known commercial nature upon which the tie processing equipment is supported. Because the frame 300 may take any number of forms and shapes, which are conventional, no extended explanation thereof for purposes of this description is necessary, it being well within the skill of those in the art to construct a framework 300 of suitable size, shape and makeup.
Reference is now made to
Two narrow flat trays 306, rigidly mounted to a crossbar 308, are displaced by extension and retraction of piston rod 310 from cylinder 312, under command of the control 314. The distal end of the piston rod 310 is rigidly connected to the crossbar 308. The trays 306 carry, at the distal end of each, an idler roller 316 which, as the piston rod 310 is extended and displaces the trays 306 from left to right, adjacent to the serrations 302, as viewed in
With reference to
Above the bundle 103 of ties 102 at the entry station 108 is a horizontally displaceable revolving conveyor, general designated 320, which comprises a belt 332.
As shown in
The scissor lift 340 is displaced up and down, by inflation and deflation of air bag 354, under the command of the control 314. Side rollers 343, preferably at several locations, rotatably engage a vertical surface of frame 300 to insure that scissor displacement is vertical. In the position of
At this time, the scissors lift 340 is once more activated so that the structural members 350 and 352, along with the bundle of ties are elevated, as explained above, by a vertical distance equal to one row of ties, at which time the air bag 354 is rendered idle, by command of the control 314, and the above-desired process of displacing an additional top row of ties toward the tie separation station 114 follows. Thus, the scissors lift 340 powered by air bag 354, which is part of the scissor's lift, once more lifts the bundle of ties upwardly by a distance of one row of ties. At this point in time, the angle iron 328 is again displaced through a full cycle to its beginning position to displace another row of ties.
When the entire bundle of ties 103 have been so displaced, top-row-by-top-row, toward the tie separation station 114, the scissor lift 340, under command of the control 314, is lowered by full deflation of air bag 354 back to its initial lowest position, preparatory to receiving the next bundle 103 of ties 102.
Reference is now made to
Once a row 106 of contiguous ties 102 has been dispatched from the entry station 108, as explained above, the respective ties 102 are directly superimposed upon a series of knurled rollers 372. Each knurled roller 372 is non-rotatably joined to an associated shaft 374, there being a number of knurled rollers 372 per shaft 374 equal to the number of ties in the process of being separated. In addition, the knurled rollers 372 are linearly displaceable along their associated shafts, with the exception of the central knurled roller 372 of each shaft 374, which central rollers 372 do not slide.
The relationship between each slideable knurled roller 372 on the associated shafts 374 is shown in
The spaced shafts 374 are power driven, each being journaled at their respective ends at 380. One of the journals 380 of each shaft 374 comprises a drive mechanism by which a power drive 382 rotates the five knurled rollers 372 and the associated shaft 374 to displace the row of ties 102 of one row 106 along the processing path after ties 102 leave the entry station 108. The power drive 382 (
The control 314 also instructs hydraulic or pneumatic cylinders 390 and 392 (
When the ties 102 at the separation station 114 are correctly outwardly positioned, as best illustrated at
Conventional camera oversight may be used to verify that the ties are in the correctly spaced and parallel relationship, as they move from the tie separation station 114 to the drilling station 118.
In further reference to
Reference is now made to
Suspended from each U-shaped frame 420 are two spaced piston rods 424, each firmly connected at their top distal ends to the associated horizontal portion of the U-shaped frame 420 via connectors 426.
Each piston rod 424 is reciprocated by an associated cylinder 428. The lower end or base of each cylinder 428, at 430, is anchored at a connection plate 431 to one of the reciprocating horizontal beams 432. Thus, there are two spaced beams 432, which move up and down responsive to operation of the four cylinders 428, two for each beam, extending and retracting their associated upwardly-directed piston rods 424 to move the cylinders 428 and beams 432 up and down. The two beams 432, adjacent to their respective ends, engage, at each location, spaced vertical guides 434, so that the beams 432 are accurately moved vertically up and down in the guides 434 by activation and deactivation of the cylinders 428 caused by fluid displacement from hydraulic or pneumatic reservoir 436, under command of control 314.
When the spaced ties 102, received from the tie separation station 114, have fully and accurately arrived at the drilling station 118, as shown in
The space ties 102 of the row 106 of ties are displaced to, through and beyond the drilling station 118 by a series of knurled rollers 440, each non-rotatably and non-slidably mounted to an associated power-driven shaft 442. Each shaft 442 is journaled at its respective ends 444. One end 444 is equipped with a drive sprocket or the like by which a chain or belt drive, under control of power drive 446, is periodically activated to turn the knurled rollers thereby bringing the ties 102 into the drilling station 114 and later out of the drilling station 114, after the ties have been drilled. The power drive 446 operates under the command of control 314. Each shaft 442, in the embodiment of
Reference is made to
The cylinders 428, (
When the drill holes 128 (
When all of the ties 102 of the spaced row 106 at drilling station 118 have been drilled in the manner described above or a variation thereof, the control 314 commands the power drive 446 (
Reference is now made to
Each spaced tie 102 arriving at the drilling station 118 passes through a cylindrical open ended barrel 470 to aid in accurately placing the ties at the drilling station 118, properly aligned and parallel spaced relation, as explained in greater detail below. At the ingress portion and at the egress portion of the drilling station 118, a transverse U-shaped frame 472 is located, supported by spaced beams 422, which are parallel to the processing path, supports the U-shaped structural members 420. Both supports 472 are in vertical planes.
A series of cylinder assemblies 474 extend vertically downward from the horizontal portion of the U-shaped frame 472 at the ingress portion of the drilling station 118, extending perpendicular to the processing path. Similarly, a plurality of cylinder assemblies 476 are disposed and extend vertically downward from the horizontal portion of distal U-shaped frame 472 near the egress portion of the drilling station 118, also perpendicular to the processing path. The function of the cylinder assemblies 474 and 476 will be explained in greater detail hereinafter.
A set of horizontally disposed cylinders 478 equal in number to the number of ties 102 in the row 106, are positioned at and somewhat beyond the distal ends of the ties 102, as shown in
In reference to
Once the ingress tie 102 is centered in the barrel 470, the leading saw kerf 477 is detected by a kerf sensor 479 which causes the control 314 to halt tie displacement and causes the barrel displacement mechanism to rotate and lift the barrel 470 and the associated centered tie utilizing motor 490 (
The raising and rotating of the barrel and the tie in the barrel inverts both by 180 degrees thereby placing the saw kerf 477 on the bottom, where drilling will later occur.
As best shown in
Five sets of vertically-displaceable spreadable alignment forks 510, each comprising two downwardly-directed bifurcated fingers 511, each of which depends from and is rigidly secured at the upper end to the lower surface of one of two cross beams 432. Thus, there is one fork 510 comprising bifurcated cantilevered fingers 511, located in aligned relation at each side of each beam 432, at two separate locations, as best seen in
The split fingers 511 of each fork 510 are designed to ensure that the associated tie is not skewed, but is precisely transversely and longitudinally positioned at the drilling site 114, prior to drilling. To ensure this accuracy, the cylinders 428 are activated by reservoirs 436 causing the piston rods 424 to extend. Because the U-shaped supports 420 are fixed in position, the extension of piston rods 424 cause the associated cylinders 428 to move downward, thereby moving the cross beams 432 down also. As the cylinders 428 move downward, the split fingers 511 of each fork 510 engage the associated roller 512 on opposite sides of the tie 102. Each roller 512 is sized and positioned so that the split fingers 511 of the associated fork 510 engage the associated roller 510 in such a way as to spread the two fingers 511 around the roller 512, as best shown in
At this point in time, command from the control 314 activates a hydraulic or pneumatic reservoir 530 (
At the same time, a stop 540 is positioned in abutting relation with the associated tie 102 at the proximal end of each tie at the drilling station 118 so that the proximal ends of all ties are disposed in a common transverse plane.
When the ties 102 at the drilling station 118 have been drilled preparatory to receiving plates 134 and spikes 158, the stop 540 for each tie is elevated by fluid from reservoir 543 moving the cylinders 535 and piston rods 537 from the position of
Reference is now made to
Reference is now made to
As shown in
Each plate 134 deposited upon the top surface of inclined belt conveyor 586 moves upward via drive shaft 589 displaced by power drive 598, under command of the control 314, so that the plate 134 is in contiguous contact not only with the top surface of conveyor 586 but also with the bottom surface of a second inclined belt conveyor 588. Conveyors 586 and 588 are parallel and, therefore, equally inclined. Top conveyor 588 is also driven by power drive 598 via drive shaft 587, under command of control 314, so as to be synchronized with conveyor 586, driven by drive shaft 589, as well. The two inclined but spaced and parallel conveyors 586 and 588 hold each plate 134 engaged between them so that no plate 134 slides downwardly or becomes skewed during the plate-conveying process. Conveyors 586 and 588 are equipped with idler rollers 592 and 594, respectively. When a plate 134 reaches the upper distal end of conveyor 586, the plate 134 is discharged onto a generally horizontal belt conveyor 597, which, as shown in
At one side edge of the conveyor 597 and slightly above the conveyor 597 is an edge guide, generally designated 610, along which upright plates 134 sequentially slide during displacement, whereby each plate 134 is precisely orientated for further displacement along two processing paths.
Recessed into the edge-guide 610 adjacent to a transverse stop-guide plate 622 are two recessed push blades 612 and 684, such that, as shown in
Conveyor 630 is displaced by power drive 598, under command of the control 314, a power drive shaft 633 being provided for that purpose. The other end of the conveyor 630 comprises an idler shaft 634.
The immediately foregoing description relates to a first tie plate 134 to reach the conveyor 597 and thence conveyor 630. Since tie plates must be provided at two locations on each tie, the present system provides for placement in spaced receptacles 660 of two spaced tie plates 134.
To place a second tie plate in a second receptacle 660, the piston rods 662 are retracted into their respective cylinders 664.
With stop-guide 622 elevated, the next tie plate 134 moving upon the top surface of conveyor 597 and sliding along edge-guide 610, encounters a second transverse stop-guide plate 670.
The control 314 activates cylinder 680, causing its piston rod 682 to extend. At the distal end of piston rod 682 is integrally connected a recessed push blade 684, which is extended by extension of the piston rod 682, thereby transversely displacing the tie plate 134 along transverse stop-guide 670. This transfers the tie plate 134 from the conveyor belt 597 onto conveyor belt 630.
With the conveyor belt 630 activated for rotation by the power drive 598 (
As this occurs, one edge of the second tie plate 134, being so displaced, moves contiguously along one surface of the side guide 638 until guide-stop 704 is contacted. In this position, a push plate 706 is disposed in a recess in the guide 638, via retraction of piston rod 708 into cylinder 710, the distal end of the piston rod 708 being integrally attached to the push blade 706. The cylinders 712 are activated so that their respective piston rods 714 are extended, holding the stop-guide 704 in its down position. The piston rods 714 are integrally connected, at their respective distal ends, to the top of the transversely-disposed stop-guide plate 704, so that stop-guide plate 704 stops the second tie plate 134, when the stop-guide 704 is in its down position thereby preventing the plate 134 from moving farther along the conveyor 630 beyond the stop-guide plate 704.
At this point, under command of the control 314, fluid from the reservoir 618 (
In further reference to
It is to be appreciated that the stop-guides 622, 670, 636 and 704 will be slightly above the top of the conveyors 597 and 630, respectively, so as to not interfere with the rotation of the belts of conveyors 597 and 630.
In reference to
With one magazine 660 full of stacked tie plates 134, top down, as shown in
With reference to
Each spaced tray or shuttle 754 and 756 is displaced by power drive 766, under command of the control 314, the spacing between plates 134 on each tray or shuttle 754 and 756 being equal to the spacing between the ties 102 at station 129.
The trays or shuttles 754 and 756 remain in the plate installation position mentioned above until and while the tie plates 134 thereon are elevated and spikes 158 are later installed through apertures in the tie plates 134, the spikes 158 being pressed into the respective ties at the previously created drill holes, in the ties 102, as explained herein in greater detail. After the spikes 158 are installed and the plate-to-tie-holding mechanisms withdrawn, trays or shuttles 754 and 756 are retracted by power drive 766 for repeated use with the next set of ties 102 at the station 129. An installed tie plate 134, with spikes extending there through is shown in
The two trays or shuttles 754 and 756, each fully loaded with inverted plates 134, are fully linearly inserted along tracks 762 and, with the railroad ties 102 correctly positioned at station 129, under command of the control 314, fluid from the reservoir 768 (
Each displacement head 772 also integrally carries three vertical rods 778 and 779, which are longer than the associated stud 774 and are positioned to correspond precisely with three of the apertures in the plate 134 to be lifted by the associated spring 776. Rod 779 is slightly longer than rods 778.
All of the cylinders 770 are activated simultaneously by fluid from reservoir 768, (
At the top distal end of each spring 776 is carried a spike-receiving header, generally designated 780.
Reference is now made to
Sequentially, the spikes 158, at the heads 161, are successively displaced into the interior of an inclined arm 794, at bifurcated distal end 796.
In the position shown in
With reference to
At opposite ends, the framework 814 is mounted on two parallel spaced tracks 830, each mounted in the same horizontal plane on spaced beams 832, so as to be perpendicular to the length of the framework 814. At the underside of each end of the framework 814, toward the lower corners thereof, are a pair of downward directed U-shaped guides 834, which are aligned to allow the framework 814 to move rectilinearly along the two spaced tracks 830. This rectilinear displacement along tracks 830 is caused by fluid displacement from reservoir 836, under command of control 314, delivered to a fluid cylinder 840.
The cylinder 840 is attached to a central stationary beam 842, at the top surface thereof, with the piston rod of the cylinder 840 rigidly connected, at its distal end, to the framework 814, allowing for to-and-fro displacement of the framework 814 to position the framework 814 in different positions to effectively and accurately place spikes 158 from revolving cylinder 815 into tie 102 through apertures in tie plate 134, as explained further below.
The top surface of beam 842 is in the same horizontal plane as the top surfaces of beams 832. Each spike 158 discharged from revolving cylinder 815 sequentially move linearly away from the cylinder 815 essentially parallel to beams 816. More specifically, the cylinder 815 causes each spike 158 to be sequentially issued therefrom onto a reciprocal tray 844. The cylinder 846 (
In continued reference to
Reference is made to
Motor 862 and gear box 860 are activated so that the cylinder 815 and the spike 158 in slot 867 are jointly rotated through essentially 90°, thereby positioning the spike head 161 perpendicular to the spike displacement path so that the head 161 is correctly oriented for proper insertion through a plate aperture into a drill hole in the tie.
When the spike 158 is to be discharged from slot 867 of cylinder 815 control actuates cylinder 817 causing piston rod 819 to extend thereby lifting the cylinder 815 a distance sufficient to avoid interference between the cylinder and the head 161 of the spike 158 as the spike 158 is discharged from the cylinder 815.
In reference to
Once a spike 158 has been installed through an aligned aperture in a tie plate 134 into the body of the tie 102, the rod 870 is retracted, as is the rod 864, into their respective initial positions, preparatory to receiving an additional spike 158, head 161 down and properly oriented, from the revolving cylinder 815. To correctly position the next spike, the cylinder 840 (
The revolving cylinder 815, the gear box 860 and the motor 862 are mounted upon a support plate 861, carried upon columns 863, which are connected to and transfer their respective loads to the framework 814.
Reference is now made to
Ties 102, each with two plates 134 held by spikes 158 at the lower surface are displaced by a conveyor system 910 (
When it is desired that the tie 102 engaging the stop 934 comprise part of a lower row or tier 906 of ties 102 on the framework 902, two hydraulic cylinders 940 comprise piston rods 934 are activated with fluid from reservoir 942, under command of the control 314, so that the stop 934 is lifted a sufficient vertical distance to allow the tie 102 to pass under the elevated stop 934. More specifically, the cylinders 940 comprise piston rods 944, which are connected at their respective distal ends 942 to the stop 934 and the base 942 of each cylinder 940 is connected to a stationary cross-bar 945 of the framework 902 in rigid relation. The piston rods 944 are extended and retracted by fluid operation of the cylinders 940. Because the distal ends of the piston rods 944 are integrally joined to the top of the stop 934, when the piston rods 944 are retracted, the stop 934 is elevated and when the piston rods 944 are extended, the stop 934 is lowered into the position shown in
The transverse stop 934 is disposed directly adjacent to each incoming tie 102 once the tie has been discharged from the rack 912. The pair of motor-driven knurled or spiked conveyors 936 and 938 are displaced by activation of a power drive 949 via motors 938, under command of the control 314, bringing the incoming plated tie 102 into contact with the stop 934 with the plates 134 on the top surface thereof up. When the stop is lifted by retraction of piston rods 944, the first tie 102 is displaced onto spaced knurled conveyors 954 and 956 to a lower row forming site 946. Knurled conveyors 954 and 956 are selectively displaced by motors 950 and 952, under command from control 314.
The orientation of incoming ties 102 is in the same horizontal plane as the ties being grouped as a row on a lower tier 946 of the framework 902, adjacent to tie row exit site.
The next plated tie 102 is processed at the station 900 to a second tier 960 of plated ties 102, located in space relation above the first tier 946 of plated ties, with the plates up at both tiers. This is done by stopping an incoming tie 102 at the stop 934 and lifting the stop 934, in the manner explained above. Momentary activated conveyors 936 and 938 place the second tie 102 to a position above short beams 962 and 964. Thereafter, the tie 102 is elevated, using the two short beams 962 and 964. Beams 962 and 964 are respectively mounted at the distal ends of piston rods 965 extending from four hydraulic cylinders 966, two for each beam 962 and 964. The piston rods 965 which are directed upwardly. The base of each cylinder 966 is rigidly attached to frame 902. Accordingly, when the piston rods are extended, the cylinders 966 remain stationary. When the beams 962 and 964 are elevated, the top surface of each beam 962 and 964 engages the bottom surface of the second tie 102. This lifts the tie 102 upward so that it becomes horizontally aligned with the second upper tier 960. This position is shown in
With the second tie 102 positioned as shown in
When the push blade 967 has so displaced a tie 102 onto conveyors 970 and 972 the push blade 967 is retracted into the position of
This process continues until there is a full row of plated ties 134/102, plates up, at both tie tiers 946 and 960, at which time, the rows of ties may be removed by a fork lift and stacked for future use, or in the alternative, dispatched to an automated railroad track prefabrication station by fork lift or on a conveyor. In lieu of delivering plated ties 102 alternatively to tier sites 946 and 960, an entire row of ties may be placed at one tier site before placement of plated ties at the second tier site.
Reference is now made to
Once the track section is completed, consisting of a desired number of plated ties and two secured rails 200, the track section is removed from the track prefabrication station 184 using a hoist 1008, such as a crane, a forklift or some other type of track section transport mechanism. At this point, the track section so removed from station 184 is either placed in inventory 189 or immediately loaded on to a transport vehicle 191 for delivery to an installation site comprising either a new railroad line or a railroad line being repaired.
If a bundle 1002 of plated ties 134-102 is dispatched from inventory 161, rows 106 of the ties 102 may be sequentially displaced from site 10002 using the system heretofore described in respect to
Thus, either way, a single row of ties becomes dispatched at tie separation site 1004, where the rows of side-by-side ties 102 may be separated utilizing the system heretofore described in respect to
As is apparent from
At the track-prefabrication station 184, it is important that the spacing between the parallel ties be equal to the spacing between ties on a railroad line and that the length alignment of the ends of the spaced parallel ties at station 184 be disposed in two spaced parallel vertical planes. This may be done using the spacing and alignment mechanisms disclosed in conjunction with
In reference to
With the ties 102 at station 184 positioned as shown in the plan view of
In reference to
The conveyor 1028 is mounted upon shafts 1032 comprising sprockets or pulleys at each end, with the upper sprocket or roller 1033 being selectively driven by motor 1032, under command of the control 314. Likewise, conveyor 1031 comprises journaled shafts 1034 at each end with one being selectively driven by motor 1036, under command of the control 314.
Once the pair of spaced rails have been discharged from conveyor 1028 onto conveyor 1031, the trailing end of each rail is engaged by a vertical leg 1039 of an angle iron 1038, which is disposed transverse of the conveyor 1031.
Continued displacement of the conveyor 1031, with the push blade 1038 integrally transversely connected to the belt 1040, pushes the two parallel rails 200 fully into the station 184, each rail 200 being aligned with and ultimately resting upon the two series of tie plates 134 at the station 184. This alignment is such that the push blade 1038 pushes the two rails 200 along the two sets of plate channels 157, until the rails are properly superimposed on channels 157 along the two series of tie plates 134, at which time the motor 1036 discontinues rail displacement. During this interval, the cylinders 1016 and piston rods 1022 hold the beam 1020 firmly across the top surfaces of all ties 102 at the station 184 to prevent misalignment of the ties 102.
As the two rails 200 are so displaced into station 184, parallel guides 1050, disposed on each side of each incoming rail 200 ensure lineal displacement of the rails 200.
Once the rails 200 are correctly positioned at station 184, the control 314 causes both the motors 1032 and 1036 to discontinue rotation until such time as the track section being assembled at station 184 is removed as a completed track section from the station 184.
Reference is made to
Reference is now made to
Once a bundle is disposed at the entry station, the rows of ties on the top of the bundle are successively displaced from the bundle, with the ties in side by side contiguous relation onto spaced conveyors, which are incremental driven consistent with drilling, plating, spiking and clipping requirements. The rows of ties so displaced in succession onto spaced conveyors are disposed perpendicular to the processing path.
The contiguous row of ties is moved by the spaced conveyor to a drilling station, where six blind bore holes at two spaced sites on the ties are drilled from beneath in an upward direction. At the time of drilling, the tie at the drilling station is caused to be spaced from the other ties of the row so as to accommodate holding the tie stationary as drilling takes place. The two arrays of blind bore drilled holes are accurately located so as to respectively receive a tie plate over each blind bore drill holes to accurately define the gauge of a track section, as hereinafter more fully disclosed. The drilling of each tie at the drilling station is presently preferred to be one tie at a time.
When the entire contiguous row of ties has been drilled, as described above, the spaced ties travel on the two spaced conveyors to a tie inversion station, where a rotating wheel receives the ties are discharged from the wheel one-after-another, so that each tie is rotated and inverted through essentially 180 degrees so that the blind bore drill holes face upwardly. Furthermore, as the inverted ties are discharged from the inversion wheel by centrifugal force aided by gravity, the ties so discharged remain spaced one from another a desired distance.
The spaced conveyors, thereafter, displace the spaced ties, blind bore drill holes up, to a tie transfer station. For each tie, the spaced conveyors are stopped, the ties are individually transversely displaced from the spaced conveyors onto a plate, spike, clip and rail-receiving station for the purpose of refabricating a section of railroad track.
Two spaced rails, disposed at a rail discharge station are positioned at that station so as to be spaced one from another at the desired gauge, using vertically-oriented rollers engaging the gauge flange of both railroad rails and outside stationary vertically-extending bars constraining against displacement of the rails except for parallel lineal movement. The bottom of the lower flange section of each rail is contiguously engaged by drive rollers, each of which is sloped downwardly toward the gauge side at an angle equal to the slope of the channel in the tie plates. Thus, when the rails are later displaced over installed tie plates on ties, as explained hereinafter, both the rail and the channel of the plates are at the same angle or slope. The rails are incrementally displaced in parallel relation by the motor-driven lower rollers, as required for placement on plated ties used to form a railroad track section.
For each tie, displaced from the tie transfer station to the plate, spike, clip and rail-receiving station, robots are provided which obtain, respectfully, plates from inventory, spikes from inventory and clips from inventory. The plates are accurately robotically positioned directly over the upwardly directed blind bore drill holes at two sites on each tie. Preferably, at least three spikes are robotically delivered to locations directly above the tie plate apertures and the spikes are then displaced downwardly through the tie plate apertures into the blind bore drill holes in the ties so as to secure the plate, in each case, to the tie and to secure the two rails, which have been advanced over the tie plates into firm retained relationship. Two spaced tie retaining clips are robotically placed on the lower flanges of each rail between adjacent ties so that the spacing between these ties is both established and retained as track sections are created and are transported to an installation site.
In addition, joint bars from inventory are robotically delivered to the distal end of the two track section rails, where one is bolt-secured to each rail so as to extend beyond the rail. The joint bar extension beyond both rails accommodates bolting of one track section to another track section in the field, at an installation site.
For further descriptive information in respect to
Each rail at station 1002 is supported upon a series of rollers 1108, each of which is contiguous with the bottom surface of the flange of the associated rail. Rotation of rollers 1108 is by motor 1110, under command of the control 314, which causes the rollers 1108 to power rotate. Since the rails 1102 rest contiguously upon the rollers 1108, rotation of the rollers 1108 displaces the rails 1102 from left to right, as viewed in
The surface of each roller 1108 is slightly sloped or at an angle in respect to the horizontal, that angle equaling the slope of the channel 157 of the railroad plates 134 on which the rails ultimately are placed. To be clear, the slope of the shafts upon which the rollers 1108 turn and the rollers 1108 themselves are inclined from the field side to the gauge side, in other words inwardly toward the center between rails 102.
The destiny of the rails 102, by reason of the above-mentioned incremental displacement, is to be successively positioned on top of tie plates, with the plates spike secured to ties, and to which clips are added, as explained hereinafter in greater detail.
The incremental advancement of the rails 102 at and from station 1102 is controlled by two commercially available optical encoders 1114, which sense the movement and location of the rails 200, at any given point in time, and cause associated pop up stops 1116 to elevate at the appropriate point in time to stop displacement of the rails, thereby assuring the correct positioning of the rails 200 at the end of any incremental advancement. At the same time, under command of the control 314, the motor 1110 is disabled, consistent with rail stoppage, to be re-enabled once an additional incremental displacement of the rails 200 is appropriate.
With further reference to
Once a row of ties is disposed at station 1120, the entire row is located on and incrementally displace along a first set of spaced parallel conveyors 1126. The displacement of each successive row of ties, with the ties contiguous one with another, is incremental, with the ties being disposed perpendicular to the displacement path defined by the spaced conveyors 1126. Preferably, the conveyors 1126 comprise log chain conveyors, where the ties rest directly on the top of the links comprising the chains, without the need for knurled or serrated chain surfaces.
The incremental displacement of transversely-disposed ties on conveyors 1126 is controlled by motor 1128, under command of control 314. The conveyors 1126 are displaced around a distal power driven shaft 1130, with a proximal idler shaft accommodating rotation of the two conveyors 1126 at the proximal end. Thus, the motor 1128, under control 314, will periodically rotate the drive shaft 1130, stopping the shaft 1130 and the conveyors 1126, at precision stationary points, as explained herein in greater detail.
The motor 1128 is disabled and the conveyors 1126 are caused to stop near an underside drilling station 1140. At this location, the ties of the lead row of ties is spaced from the other ties of the row, to accommodate holding the tie accurately stationary during drilling in an upward direction. Each tie sequentially drilled from the bottom up is caused to be so separated from the remainder of the ties of the row. Twelve blind bore drill holes are drilled in the lower surface of each tie, six at two spaced locations, i.e. precisely where two tie plates will ultimately go. The depth of the blind bore drill holes may be determined by those skilled in the art, five inches typically being suitable. As the ties 102 are sequentially upwardly drilled at station 1140, several hold down clamps 1142 accurately retain the ties in a stationary position to produce the twelve blind bore drilled holes, six at each of the above mentioned two locations. Upward drilling is advantageous in that gravity tends to empty drill shavings from the blind bores, the weight of the tie tends to help hold the tie in place, and emptied drill shavings may be easily disposed of, for example on a separate conveyor under the drill station. After the first tie of the row is so drilled, the motor 1128 incrementally advances the conveyors 1126 and the next tie in the row is spaced from the row and drilled in like manner at station 1140. Thus, when all of the ties of the row at station 1140 have been drilled in like manner, the motor 1128 further increments the conveyors 1126, bringing the row of spaced ties forward to a tie inversion station 1144.
With further reference to
When the row of spaced ties arrive at tie inversion station 1144, such is detected by encoders 1150 causing stops 1152 to be enabled appropriately bringing the conveyors 1126 and the row of ties resting thereupon to an accurate stop. At tie inversion station 1144, an inversion wheel, hereinafter explained in greater detail, receives and, rotates the ties sequentially in a distal direction, causing the drilled bottom surface of each tie to become the top surface. This places the blind bore drill holes facing upwardly, rather than downwardly. The ties are separately and sequentially so inverted at the station 1144 and are discharged from the inversion wheel in spaced relation, each discharged tie resting upon the top of conveyors 1120, as the conveyors are caused to be incrementally displaced by motor 1128, under command of the control 314. As the spaced row of ties arrives near the distal end of the conveyors 1126 at the drilled tie discharge station 1164, such is detected by optical encoders 1160, which activates pop-up stops 1160 thereby bringing the spaced chain conveyors 1126 to a stop.
The encoders 1114, 1146, 1150 and 1160 may comprise Model H20, manufactured by BEI Sensors.
Thereafter, ties are displaced lengthwise (transverse to conveyors 1126) in succession from the drilled tie discharge station 1164 to a plate, spike, clip and rail assembly station 1112, so as to rest upon a second set of log chain conveyors 1170, at the proximal end thereof, for purposes later to be explained. This displacement is diagrammatically illustrated at line 1172 in
With specific reference to
Once a tie, with drill holes up, has been received at station 1112 perpendicular to the space conveyors 1170, two plates from inventory 1180 are magnetically retrieved by two plate robots 1182, one on each side, under command of control 314, and accurately placed in superimposed relationship over the two sets of six blind bore drill holes exposed at the upper surface of the tie 102 at station 1120.
Thereafter, spikes from inventory 1184 are magnetically retrieved by spike robots 1186, under command of control 314, typically in groups of three. These three spikes are magnetically carried in correct space relation by robots 1186, so as to be first positioned over three of the apertures in each plate 134 and thereafter forced inserted by robots 1186 through the plate apertures into the aligned blind bore drill holes until the rail-retaining spikes are partially inserted and the plate-retained spikes are fully inserted. Of course, more than three spikes may be inserted at each plate location, as determined by those skilled in the art. Where three are used, two are rail-retaining spikes, one on each side of the associated lower rail flange and one is a plate-retaining spike, holding the plate firmly against the tie. After the rails are correctly positioned on the two plates, the rail-retaining spikes are fully inserted by spike robots 1186.
Tie spacer clips are retrieved from inventory 1190 by two robots 1192, under command of control 314, and are transversely force inserted on the lower flanges of both rails, as hereinafter more fully explained, to accurately and correctly establish the spacing between ties of the track section being assembled. In this embodiment, it is presently preferred that two clips, placed accurately in space relation, will establish and retain the spacing between ties after being force-fit around the lower flange of each rail, as hereinafter more fully explained.
Once a tie has been plated and spiked, as well as receiving the two rails and correctly spaced clips, that tie is advanced by conveyor 1170 powered by motor 1128, under command of control 314, a distance equal to the spacing between ties required for a section of railroad track. At the same time, the rails are displaced through the same distance by rollers 1108 powered by the motor 1110, under command of control 314. This sequence continues, tie-after-tie. Thus, as one completed tie is plated and spiked so as to be firmly associated with both the tie and the rail, the rails and the associated ties are incrementally moved forward by the space required between ties. At this point another tie is perpendicularly inserted along path 1172 into station 1112 and the process is repeated.
Ultimately, sufficient ties have been so processed and the rails have been so advanced that a section of track has been completed and rests upon conveyors 1170. Typically, such a track section may comprise 40 feet of track, weighing on the order of 1,100 pounds. This allows for facile removal of the track section from the conveyors 1170 for placement in inventory or on a transport vehicle and from thence to a track installation site. Typically, at one end of the track section, the rails may extend 25 inches beyond the last tic.
But before a track section is removed, a joint bar for coupling rail sections together is delivered to and fastened to the distal end of the rails comprising the track. Also, joint bars may be coupled between rails at intermediate portions of the track section, as determined by those skilled in the art.
More specifically, from inventory 1191 two joint bars at a time are removed by joint bar robots 1193, under command of control 314.
Once a track section has been removed from the conveyors 1170, using suitable lifting device and either placed in inventory or on a transport vehicle, the process of forming the next track section begins.
Reference is now made to
Each rail-displacement roller 1108 is journaled to a steel support bracket 1202, each roller 1108 being rotationally supported by its steel bracket 1202 and rigidly mounted to the top surface of the associated horizontal beam 1196. Each roller 1108 is supported by two spaced bearings 1204, carried in parallel relation by the associated bracket 1202, a shaft 1206 rotationally extending through the two bearings 1204. Each shaft 1206 is non-rotatably joined to its associated roller 1108 in a key/keyway relationship, with each shaft 1206 journaled for turning in bearings 1204. More specifically, each bearing is non-rotatably positioned within a mounting plate 1208 secured by bolts 1209 to each associated plate attached to bracket 1202, as best shown in
Each shaft 1206 is mounted so as to be slightly sloped downwardly from field to gauge at an angle equal to the slope existing on channel 157 of each plate 134. Typically, depending upon the type of plate, the slope may be between 1:30 and 1:40.
As shown in
A series of cross beams 1200 rest upon and are rigidly secured at each end thereof to the space longitudinal beams 1196, as best shown in
For further detail concerning the tie bundle entry station 1124, reference is now made to
A scissors lift, generally designated 1234 is rigidly mounted at its base 1236 to the two cross beams 1232 at lower frame 1236. The scissors lift 1234 is preferably a commercially-available Southworth of suitable capacity, which is lifted and lowered by activation of air bag 1238, responsive to commands from control 314. Air bag 1238 is an integral part of the commercially available scissors lift 1234.
Resting upon the top of the scissors lift 1234 is a rectangular framework 1240. Within the framework 1240 are rotatably mounted, spaced parallel idler rollers 1242. The framework 1240 and the idler rollers 1242 are shown in their lowest position in
With a tie bundle accurately positioned on idler rollers 1242, so that the ties are perpendicular to the rollers 1242, the control 314 activates air bag 1238 to elevate the scissors lift 1234 a distance sufficient for the top row of ties of the bundle to be aligned with discharge space 1250, directly above framework plate 1252. As shown in and described in relation to
At this point in time, under command of the control 314, the air bag 1238 incrementally elevates the scissors lift 1234 vertically to bring the next row on the bundle of ties into alignment with the discharge opening 1250 and the push plate 1264, at which time the new top row is timely displaced into the station 1120, in the manner explained above.
At station 1120, each row of ties there-received is positioned on idler rollers 1270, which are rotationally mounted on a frame 1272 perpendicular to the incoming ties.
In reference to
When the ties are fully positioned on the rollers 1270 at station 1120, the one or more cylinders 1274, under command of the control 314, lowers the frame 1272, which in turn lowers the idler rollers 1270, leaving the lower surface of the row of ties resting on top of the spaced conveyors 1126, with the rollers 1270 spaced a desired vertical distance below the bottom surfaces of the ties.
Reference is now made to
Thus, responsive to sequential activation of motor 1292, under command of the control 314, the space chain conveyors 1126 with a row of ties 102 resting transversely on the top surface thereof, cause the row of ties to be displaced from the tie row-to-conveyor station 1120 to the underside drilling station 1140.
The frame 1272 and the rollers 1270 have been removed from
Each row of ties 102 leaving the tie row-to-conveyor station 1120 are displaced distally by engagement with the top of moving conveyors 1126. As one row of ties 102 is positioned accurately at station 1140, encoders 1146 detect this and cause the pop-up stops 1148 to elevate, thereby holding the row of ties stationary, except for the lead tie.
Continuing reference is made to
The lead tie 102 is transversely displaced against a push blade 1303, recessed in an abutment wall 1301. This distance can be relatively small, as determined by those skilled in the art. By doing so, the tie is accurately positioned over the underneath drill heads for accurate drilling. This displacement is illustrated in
It is presently preferred that drill heads comprise commercially manufactured AutoDrill drill heads, used essentially in the manner disclosed herein in respect to
In addition to longitudinally securing the tie to be drilled between push plates 1309 and 1303, as mentioned above, the tie 102 to be drilled is held against misalignment and rotation by a clamshell holding mechanism, generally designated 1311. The holding device 1113 comprises two cylinders 1303, the piston rods 1313 of which are extended by fluid displacement from reservoir 1315, under command of the control 314.
The distal ends 1317 of the piston rods 1313 are rotationally connected respectably, each at a coupler 1319, to spaced arcuate blades 1321. Thus, when the piston rods 1313 are extended, the arcuate clam shell blades 1321 are both lowered, to exert a downward force on the top of the tie and are folded toward each other so as to create opposed forces on both longitudinal sides of the tie 102 at the drilling station 1140, thereby correctly longitudinally aligning the tie to be drilled and holding the tie against misalignment during drilling. Side clamping of the tie to be drilled from positions below the tie may be used in lieu of from the top, as shown in
When the drilling has been completed the holding mechanism 1311 is lifted and the control 314 instructs the motor 1128 to once more incrementally displace the conveyors 1126 with the pop-up stops 1148 first retracted and then re-elevated at the interface between the second and third ties of the row by position control encoder 1146. The conveyors 1128 increment the second tie forward into the spaced position for drilling at the drilling station 1140, in the manner explained above, while the drilled tie 102 is moved forward retaining a spaced relation with the second tie 102. When the second tie 102 is at the station 1140 and the first drilled tie is distal of the station 1142, the drilling of the second tie will occur, as explained above.
However, each drilled tie must be repositioned accurately on conveyors 1126 so that the overlap on each side is essentially equal. This is done by appropriately delivering fluid from reservoir 1331 to cylinder 1333 to extend the piston rod 1335. The distal end of the piston rod 1335 is rigidly connected to the push plate 1303 so that extension of the piston rod 1135 correspondingly displaces push plate 1303 the precise distance needed to return the drilled tie 102 to its proper position on conveyors 1126.
From the foregoing, it is apparent that the drilled ties exiting from station 1140 are in spaced relation one to the next, with the drill holes down, and are not contiguous, as tie displacement to the tie inversion station 1142 occurs after drilling.
Reference is now made to
As can best be seen in
Each plate 1302 comprises two open recesses 1332, which are 180 degrees out of phase one with another. The sets of recesses 1332 on each plate 1302 are respectfully horizontally aligned with recesses 1332 on the other plate. Each recess 1332 is defined by spaced side edges 1334 and a back edge 1336 so that each recess 1332 essentially forms three sides of a rectangle. Size of each recess 1332 is selected so as to receive, when properly located, a drilled tie into two of the aligned recesses 1332 for rotational displacement and inversion of the tie.
The plates 1302 are collectively displaced via shaft 1310 by a motor 1340, under command of the control 1314. The recesses or throats 1332 are positioned so that two of the recesses 1332, at bottom edge surfaces 1334 are directly in line with the bottom of an incoming drilled tie, drill holes down, such that continued displacement of the conveyors 1326 by a motor 1128, under command of the control 313, will displace the incoming tie into the two aligned proximately disposed recesses 1332 so that the bottom of the tie rests on the lower edges 1334 of the recesses 1332. At this point in time, the motor 1128, under command of the control 314, briefly stops the conveyors 1126 and the motor 1340. Under command of the control 314 the inversion wheel 1300 and the tie 102 are rotated through essentially 180 degrees thereby placing the drill holes in the tie in an upward position as the tie is discharged from the inversion wheel 1300, by centrifugal force and by gravity, back onto the spaced conveyors 1126.
At this point in time, the second set of recesses 1332 in plates 1302 are properly disposed proximally between the spaced conveyors 1126, preparatory to receiving the next drilled tie. The next drill tie is then displaced by motor 1128 and the conveyors 1126 into the parallel spaced proximally disposed recesses 1332 and the process of inverting a tie is repeated. As the conveyors 1126 displace the second tie into the second set of recesses 1132, the first inverted tie is moved distally along the conveyors 1126 upon which the first inverted tie rests. This process is repeated until all of the ties of the row have been inverted and the inverted ties are in spaced relation on and displaced by conveyors 1126 toward the drill tie discharge station 1164.
Reference is now made to
As the lead tie 102, resting upon and being displaced by conveyors 1126 approaches the distal end of conveyors 1126, encoders 1160 sense the final position of the tie 102 thereby causing pop-up stops 1162 to bring conveyors 1126 and the ties thereon to a stop. In this position, the tie 102 distally disposed at station 1164 is in alignment with station 1112, at the distal end of conveyors 1170.
Three sets of relatively short transfer conveyors, transverse to conveyors 1126 and 1170, are disposed in aligned tandem relation, i.e. conveyor systems 1350, 1352 and 1354. Conveyor system 1350 comprises spaced chain conveyors 1356 mounted about an idler shaft 1358 and a drive shaft 1360. Conveyor system 1350 is mounted upon a vertically displaceable frame 1362, which can be elevated to lift the associated tie upward off from conveyors 1126 and lowered to be free from interference with the next incoming tie 102. Cross struts 1359 extend between, and are connected to the frame 1362 and displaced with the conveyors 1356. Each tie rests on and is transported by displacement of cross struts 1359, which are spaced from each other by spaces 1357.
Conveyor system 1352 comprises spaced chain conveyors 1364, mounted upon an idler shaft 1366 and a power driven shaft 1368. Conveyor system 1354 is mounted upon a fixed frame 1370 at an elevation above conveyors 1126 and 1170 but in vertical alignment with conveyors 1356, when in their elevated position by reason of lifting of framework 1362, as explained below. Spaced cross struts 1365 extend between and are connected to the frame 1362 and displaced with the conveyors 1364. Each tie received by the conveyor 1364 rests on and is transported by displacement of cross struts 1365 toward station 1112.
The conveyor system 1354 is similar to conveyor system 1350 and comprises two parallel chain conveyors 1380 mounted upon and accommodating displacement around an idler shaft 1382 and a power driven shaft 1384. Spaced cross struts 1385 extend between and are connected to and displaced with conveyors 1380. Each tie received by the conveyors 1380 rests on and is transported by displacement of struts 1385 into an accurate position at station 1112. The conveyor system 1354 is mounted upon a lower frame 1386, which moves up and down, much the same as frame 1362, so as, in the down position, to avoid interference with conveyors 1170 and in the up position placing the top of the conveyors 1380 above the top surface of conveyors 1170 at essentially the same elevation as the top of the stationary conveyors 1364. Thus, when the support structure 1362 is in its upper position and the support structure 1386 in its up position, the conveyors 1356, 1364 and 1380 are at essentially the same elevation, which is above the elevation of the top of the conveyors 1126 and 1170. When all of the conveyors 1356, 1364 and 1380 are at the same elevation and operating, the tie at station 1164 is transported to station 1112, where plates, spikes, clips and rails are added. Motor 1390 drives drive shafts 1360, 1368 and 1384 under command of control 314, to displace conveyors 1356, 1364 and 1380, thereby placing the tie 102 so displaced accurately at station 1112, at which time, under command of the control 314, the motor 1390 is deactivated causing displacement of conveyors 1356, 1364 and 1380 to stop. This occurs when encoder 1389 senses tie 102 as being correctly located, causing stop 1387 to engage the distal end of the tie thereby bringing the tie to a stop. Under command of the control 314, the piston rods 1396 are retracted appropriately into the cylinders 1394, which causes the underframeworks 1154 and 1386 to return to their lower positions. The tie 102 at station 1112 thus comes to rest on conveyors 1170, out of contact with cross struts 1385.
Elevating and lowering of the underframeworks 1350 and 1386 is caused by displacement of air to and from reservoir 1392 to and from pneumatic cylinders 1394, under command of the control 314, causing the piston rods 1396 thereof to timely lift and lower the under-frameworks 1362 and 1386.
Reference is now made to the
With the plates resting properly at two locations over the blind bore drill holes 128 of tie 102, the rails 200 are advanced to a position so as to extend above and distally beyond the two plates. As mentioned earlier, the delivery of the two rails 200 is at a slight transverse angle downward from the field side to the gauge side, at a slope identical to the slope of the channels 157 of the plates 134.
With the rails advanced in this manner and then stopped, the tie and the plates are lifted vertically so that the bottom surface of the rails become firmly contiguous with the associated channel surfaces 157 of the plates 134. This causes the bottom surface of the tie 102 to vertically separate from the two conveyors 1170. The lifting is accomplished by two screwjacks 1444, under command of the control 314, such that abutments 1442 engage and lift the tie vertically, while preserving the horizontal orientation of the tie thus bringing the channels 157 of the tie plates 134 into contiguous relation with the bottom surface of the two rails 200. In reference to
With the rails 200 resting on the plates 134, as mentioned above, the tie 102 is held in the elevated position by the screwjacks 1444, while the control 314 activates two robots 1450, one located on each side of conveyor 1170, so that their respective arms 1456 are rotated and extended along paths 1463, bringing magnetics heads 1458 into superposition with a metal spike holder 1454, into which three spikes have been placed from inventory 1452.
Once the spikes are in the clamshell shuttles 1461, the empty holders 1454 are returned, under command of the computers control 314, to their initial positions to each receive three more spikes. When the three spikes 126 are fully inserted into the tie 102 from the clamshell shuttles 1461, the clamshell shuttles are returned to their initial positions, under command of the control 314, preparatory to receiving three more spikes. The paths of the arm 1456 to the pickup sites where holders 1454 are disposed is identified by dotted lines 1460. The paths by which the arms 1456 of the robots 1450 move from the pickup sites to the clamshell shuttle sites is diagrammatically illustrated by dotted lines 1462. The paths from the clamshell shuttle sites to the spike installation locations is diagrammatically illustrated by dotted lines 1463. Preferably, the robots 1450 are manufactured by ABD, model I R B 4400.
At this point in time, under command of the control 314, the rails 200, together with the attached tie 102 are advanced in a distal direction, by motor displacement of the rails. As the screwjacks 144 retract the abutments 1442, under command of control 1314, the joined tie and the rails, due to the weight to the rails move the bottom surface of the tie 102 toward contact with the conveyors 1170. Eventually contact is achieved. Conveyors 1170 turn on idler shaft 1429 and are power-driven by shaft 1430. Under command of the control 314, the conveyors 1170 are incrementally moved forward to establish, with precision, the correct spacing between ties, as additional ties are displaced, as described above, until all ties are fully and accurately positioned at station 1112.
Each tie is processed in the same manner, as described above in conjunction with the first tie, so as to position plates on the second tie, advance the rails, lift the second tie 102 until the tie is contiguous at the channels 157 at the bottom of the two ties 200, after which the plates are spiked, as described above. As to the second tie, which has been advanced, reference is made to
When the four clips have been placed on the gauge side of the two rails 200, under command of the control 314, the robots 1480 are returned to their initial positions.
Thus, in lieu of the approach described in connection with
Once the clips 4192 are loaded into the holders 1500, under command of the control 314, compressed air, for example, is delivered from reservoir 1506 to the cylinders 1504, causing extension of the piston rods 1502. This displaces the associated holder 1500 and the associated clip 1492 underneath the associated rail 200, causing the clips 1492 to engage the lower flange 202 of each rail 200 and to snap into place so as to avoid inadvertent removal. Each clip 1492, as it is being displaced, slides contiguously along the adjacent surface of the associated tie 102. The holders 1500 have a vertical dimension such that they do not interfere with the displacement of conveyors 1170 or the displacement of the ties, plates, spikes and rails mounted on top of the ties. When the clips 1492 have been correctly snapped into place beneath the rails 200, the holders 1500 are retracted into their initial positions, under command of the control 314, as the piston rods 1502 are retracted into their initial positions.
At this point in time, the conveyors 1170, under command of the control 314, advance the track section incrementally, i.e. the distance necessary for correct placement on a third incoming tie 102 at station 1112, to be added to the track section in the manner described above.
Reference is made to
In the manner describe above, the tie placement continues so that rails are superimposed upon tie plates 134 and spikes 126 inserted though the apertures to the tie plates 134 and to the blind bore drill holes 128 and the clips are snapped onto the lower flanges of the rails, as best illustrated in
It is convenient, for purposes of track section installation that the two distal-most ties on the track section sometimes be in contiguous side-by-side relation, as shown in
When one joint bar 1524 has been bolt connected to the distal end of one rail of a track section and the proximal end of other rail of a second track section, the contiguous distal tie 102 is forcibly displaced in a distal direction the precise distance required between adjacent ties. As shown in
As shown in
In lieu of the plate delivery and placement system shown and described in conjunction with
The bottom plate 1556 also comprises a longitudinal lineal slot 1562, located equal distance between the flanges 1554. A T-shaped push plate 1564 reciprocates in the slot 1562, with the top portion 1566 of the push plate 1564 being above and wider than the width of the slot 1562. As such, the top portion 1566 engages the trailing edge of the last tie plate 134 in the tray 1552. Displacement of the push plate 1564, from left to right, as viewed in
Tie plates 134 are picked one at a time by each robot 1420 and placed on a waiting trough 1554 (
Thereafter, the control 314, causes the piston rod 1584 to retract into the cylinder 1586, causing the pusher 1586 to return to its initial position.
The rectangular reciprocal push plate 1580 is positioned in a recess in one of the flanges 1554, as shown in
Ties 102 are sequentially displaced into and from the position shown in
It is to be understood that a second plate delivery and placement system 1550 is disposed at the other end of the tie 102 and operates, as described above, to precisely place a second tie plate 134 over the other set of drill holes in the tie.
Once the spikes are insert through the plate apertures into the tie drill holes, the tie and rails are spiked to form part of a track section, in a manner explained herein. As the tie is formed as part of the track section, the rails move ahead the required distance, then another tie is moved in place and two plates are positioned as described above and are spiked. This repeats until the section of track is complete.
Reference is now made to
Thus, the system 1588 comprises V-shaped sloped trough 1590 comprising downward converging planar sides 1592 and 1594. The V-shaped trough 1590 also comprises a proximal end edge 1598 and a distal end edge 1600. Adjacent to the trough distal end 1600 is disposed a spike holder 1604, also comprising part of the system 1588. Holder 1604 is slightly sloped from left to right as shown in
As spikes 158 are discharged from inventory 1452, by robot 1450, they are dropped and land at the intersection, inverted apex or merger site 1602 of the converging sides 1592 and 1594 of the V-shaped trough, tip down and head up, as illustrated adjacent to intersection 1602. The spikes 158 move downwardly in succession along the merger line 1602, by force of gravity stimulated by vibrations receive from vibrator 1608.
The cutout 1596 in trough side 1592, accommodates visual inspection of the spikes 158 as they move down the intersection 1602, as well as manual removal or reorientation by an observer to the extent necessary.
The V-shaped trough may be formed of any suitable material, such as wood, steel, aluminum or synthetic material.
The force of gravity and vibration of the V-shaped trough 1590 accommodate the spikes 158, in sequence, to move and then fall off from the distal end 1600 of the V-shaped trough 1590 in alignment with the slot 1606 so that the tips of the spikes 158 extend downwardly and the heads 161 are held above the spike holder 1604 contiguous therewith and directly above to the slot 1606. The spike heads 161 are larger than slot 1606. Thus, the series of spikes 158 are placed in the position shown in
At appropriate time, under command of the control 314, the robot 1450 is activated causing the arm 1456 to extend and swing to the extent necessary to follow path 1460 thereby bringing the magnetic head 1605, held by the pickup adapter 1458 of the robot 1450 into superposition immediately above and in alignment with one or more of the spikes nearest the right end of the holder 1604, as viewed in
While one or three spikes 158 are described as being spatially lifted at any point in time, it should be readily apparent that one, two or more than three spikes could be so processed, as determined by those skilled in the art, when that is the best choice.
With reference to
The spike placement system at station 1112 comprises one screwjack 1610 per spike to be inserted, secured at its proximal base 1611 rigidly to the frame 300. Screwjack 1610 is illustrated as comprising reciprocal rod 1612 to which a distal adapter 1614 is attached. The adapter 1614 comprises a rounded distal end surface 1616.
Activation of screwjack 1610, under command of control 314, causes the rod 1612 and the adapter 1614 to extend downwardly until the rounded surface 1616 becomes contiguous with the head 161 of the aligned spike 158 and, thereafter, drives the spike 158 downward until it is fully inserted into associated blind bore 128, with the spike head 161 firmly contiguous with the top adjacent surface of the plate 134. It is to be appreciated that the illustrated spike 158 is a plate-holding spike. It follows that when the spike 158 is used as a rail-retaining spike to ultimately engage a lower flange of the rail, the screwjack 1610 will displace the head 161 of the spike 158 downward only until the head 161 is firmly contiguous with the top surface of the lower rail flange.
When the spike 158 is fully inserted, under command of the control 314, the screwjack 1610 retracts the rod 1612 and the adapter 1614, returning the same to their initial locations.
The robotics depicted in
As is well known to those of ordinary skill in the art, the adjustment in the programming of each robot is conventionally accomplished with a hand pendant, where the robot arm end effector is moved into a position to pick a part, such as a plate, one or more spikes and a clip. A command syntax opens and closes the gripper or other device on the end of the end effector. Then the robot is moved to additional positions, which are saved as the path transversed by the robot. The path ensures that the robot arm does not contact other devices or obstacles in the vicinity of the robot. When a robot is working in conjunction with other pieces of automated equipment, conventional handshake signals are provided between the robot and the other pieces of automated equipment. This prevents collisions between the two. When a robot runs in automatic mode, the robot moves in a straight line to the next programmed position.
As depicted in
All optical sensors 315 are controlled by a master control 319, as shown in
The following tabulation correlates the functions of the optical sensors 315 and the associated activators 317:
While any suitable commercially available software may comprise part of the systems disclosed above, it is presently preferred that Schneider Unity Pro S (for PLC Software together with CNC machine technology) be used to control all mechanisms and their movements. This software easily becomes accommodating to the disclosed systems by those skilled in the art, using ordinary skill. Accordingly, no detailed software disclosure is required.
The invention may be embodied in other specific forms without departing from the spirit of the essential characteristics thereof. The present embodiments, therefore, are to be considered in all respects as illustrative and are not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced herein.